Membraneless condensates by Rapsn phase separation as a platform for neuromuscular junction formation.

Our daily life depends on muscle contraction, a process that is controlled by the neuromuscular junction (NMJ). However, the mechanisms of NMJ assembly remain unclear. Here we show that Rapsn, a protein critical for NMJ formation, undergoes liquid-liquid phase separation (LLPS) and condensates into liquid-like assemblies. Such assemblies can recruit acetylcholine receptors (AChRs), cytoskeletal proteins, and signaling proteins for postsynaptic differentiation. Rapsn LLPS requires multivalent binding of tetratricopeptide repeats (TPRs) and is increased by Musk signaling. The capacity of Rapsn to condensate and co-condensate with interaction proteins is compromised by mutations of congenital myasthenic syndromes (CMSs). NMJ formation is impaired in mutant mice carrying a CMS-associated, LLPS-deficient mutation. These results reveal a critical role of Rapsn LLPS in forming a synaptic semi-membraneless compartment for NMJ formation.

Opposed Actions of PKA Isozymes (RI and RII) and PKC Isoforms (cPKCßI and nPKCε) in Neuromuscular Developmental Synapse Elimination.

BACKGROUND: During neuromuscular junction (NMJ) development, synapses are produced in excess. By sensing the activity-dependent release of ACh, adenosine, and neurotrophins, presynaptic receptors prompt axonal competition and loss of the unnecessary axons. The receptor action is mediated by synergistic and antagonistic relations when they couple to downstream kinases (mainly protein kinases A and C (PKA and PKC)), which phosphorylate targets involved in axonal disconnection. Here, we directly investigated the involvement of PKA subunits and PKC isoforms in synapse elimination. METHODS: Selective PKA and PKC peptide modulators were applied daily to the Levator auris longus (LAL) muscle surface of P5-P8 transgenic B6.Cg-Tg (Thy1-YFP) 16 Jrs/J (and also C57BL/6J) mice, and the number of axons and the postsynaptic receptor cluster morphology were evaluated in P9 NMJ. RESULTS: PKA (PKA-I and PKA-II isozymes) acts at the pre- and postsynaptic sites to delay both axonal elimination and nAChR cluster differentiation, PKC activity promotes both axonal loss (a cPKCßI and nPKCε isoform action), and postsynaptic nAChR cluster maturation (a possible role for PKCθ). Moreover, PKC-induced changes in axon number indirectly influence postsynaptic maturation. CONCLUSIONS: PKC and PKA have opposed actions, which suggests that changes in the balance of these kinases may play a major role in the mechanism of developmental synapse elimination.

The Neuromodulator Adenosine Regulates Oligodendrocyte Migration at Motor Exit Point Transition Zones.

During development, oligodendrocyte progenitor cells (OPCs) migrate extensively throughout the spinal cord. However, their migration is restricted at transition zones (TZs). At these specialized locations, unique glial cells in both zebrafish and mice play a role in preventing peripheral OPC migration, but the mechanisms of this regulation are not understood. To elucidate the mechanisms that mediate OPC segregation at motor exit point (MEP) TZs, we performed an unbiased small-molecule screen. Using chemical screening and in vivo imaging, we discovered that inhibition of A2a adenosine receptors (ARs) causes ectopic OPC migration out of the spinal cord. We provide in vivo evidence that neuromodulation, partially mediated by adenosine, influences OPC migration specifically at the MEP TZ. This work opens exciting possibilities for understanding how OPCs reach their final destinations during development and identifies mechanisms that could promote their migration in disease.

HP1-beta is required for development of the cerebral neocortex and neuromuscular junctions.

HP1 proteins are thought to be modulators of chromatin organization in all mammals, yet their exact physiological function remains unknown. In a first attempt to elucidate the function of these proteins in vivo, we disrupted the murine Cbx1 gene, which encodes the HP1-beta isotype, and show that the Cbx1(-/-) -null mutation leads to perinatal lethality. The newborn mice succumbed to acute respiratory failure, whose likely cause is the defective development of neuromuscular junctions within the endplate of the diaphragm. We also observe aberrant cerebral cortex development in Cbx1(-/-) mutant brains, which have reduced proliferation of neuronal precursors, widespread cell death, and edema. In vitro cultures of neurospheres from Cbx1(-/-) mutant brains reveal a dramatic genomic instability. Our results demonstrate that HP1 proteins are not functionally redundant and that they are likely to regulate lineage-specific changes in heterochromatin organization.

Prolongation of evoked and spontaneous synaptic currents at the neuromuscular junction after activity blockade is caused by the upregulation of fetal acetylcholine receptors.

It has been shown previously in a number of systems that after an extended block of activity, synaptic strength is increased. We found that an extended block of synaptic activity at the mouse neuromuscular junction, using a tetrodotoxin cuff in vivo, increased synaptic strength by prolonging the evoked endplate current (EPC) decay. Prolongation of EPC decay was accompanied by only modest prolongation of spontaneous miniature EPC (MEPC) decay. Prolongation of EPC decay was reversed when quantal content was lowered by reducing extracellular calcium. These findings suggested that the cause of EPC prolongation was presynaptic in origin. However, when we acutely inhibited fetal-type acetylcholine receptors (AChRs) using a novel peptide toxin (alphaA-conotoxin OIVA[K15N]), prolongation of both EPC and MEPC decay were reversed. We also blocked synaptic activity in a mutant strain of mice in which persistent muscle activity prevents upregulation of fetal-type AChRs. In these mice, there was no prolongation of EPC decay. We conclude that upregulation of fetal-type AChRs after blocking synaptic activity causes modest prolongation of MEPC decay that is accompanied by much greater prolongation of EPC decay. This might occur if acetylcholine escapes from endplates and binds to extrajunctional fetal-type AChRs only during large, evoked EPCs. Our study is the first to demonstrate a functional role for upregulation of extrajunctional AChRs.

The muscle protein Dok-7 is essential for neuromuscular synaptogenesis.

The formation of the neuromuscular synapse requires muscle-specific receptor kinase (MuSK) to orchestrate postsynaptic differentiation, including the clustering of receptors for the neurotransmitter acetylcholine. Upon innervation, neural agrin activates MuSK to establish the postsynaptic apparatus, although agrin-independent formation of neuromuscular synapses can also occur experimentally in the absence of neurotransmission. Dok-7, a MuSK-interacting cytoplasmic protein, is essential for MuSK activation in cultured myotubes; in particular, the Dok-7 phosphotyrosine-binding domain and its target in MuSK are indispensable. Mice lacking Dok-7 formed neither acetylcholine receptor clusters nor neuromuscular synapses. Thus, Dok-7 is essential for neuromuscular synaptogenesis through its interaction with MuSK.

Quantal endplate currents from newborn to adult mice and the switch from embryonic to adult channel type.

Quantal endplate currents (qEPCs) were recorded extracellularly by a macropatch electrode from excised diaphragms of mice. During the first 3 days after birth, the mean rise time t(r) was 0.5 ms (0.1-0.9 peak, 20 degrees C). Double-exponential, amplitude-weighted fits of the decay discerned almost equally abundant components tau(1)' approximately equal to 6 ms and tau(2)' approximately equal to 9 ms. Beginning on day 3, on days 4 and 5 after birth both t(r) and the tau' dropped. Further decreasing slowly, adult values were reached at day 8, with t(r) approximately equal to 0.3 ms, tau(1)' approximately equal to 2 ms and a very weak tau(2)' approximately equal to 6 ms component. When compared to the kinetics of fetal channels, the tau(1)' and tau(2)' of up to 3 day qEPCs could correspond to the short and long splice variants of the fetal channel type. The tau(1)' of adult muscles of 2 ms agrees well with the burst durations of adult channels while a weak longer tau(2)' component may represent 'extrasynaptic' channels. The long t(r) of very young mice may correspond to the relatively slow rise of channel currents elicited by ACh pulses in mouse myoballs.

Retarded myelination in the lumbar spinal cord of piglets born with spread-leg syndrome.

Piglets born with spread-leg syndrome, a congenital weakness of the hindlimb adductors, were investigated to determine the site of lesion leading to limb impairment. Histological and immunohistochemical studies of the motor neuron unit showed no alterations but quantitative analysis revealed a reduction of axonal diameter and myelin sheath-thickness of the fibres innervating the adductors of the affected limbs. In the lumbar spinal cord a lack of myelination was observed in the tracts descending to the lower motor neurons. Recovery from the syndrome was accompanied by a catching-up of myelination with that of the controls. The spread-leg syndrome is due to a nutritional deficiency in the sow; thus it is assumed that the deficient maternal substances, mainly choline and methionine, are essential for the normal myelin production by spinal white matter oligodendrocytes of the fetus.

Localization and regulation of MuSK at the neuromuscular junction.

The receptor tyrosine kinase, MuSK, is required for the formation of the neuromuscular junction (NMJ) where MuSK becomes phosphorylated when exposed to neuronally synthesized isoforms of agrin. To understand better the mechanisms by which MuSK mediates the formation of the NMJ, we have examined how MuSK expression is regulated during development in the embryo, by neuromuscular injury in the adult and by agrin in vitro. Here we show that MuSK is associated with the earliest observable AChR clusters at the developing motor endplate and that MuSK and AChRs codistribute throughout the development of the NMJ. These two proteins are also coordinately regulated on the surfaces of cultured myotubes where MuSK and AChRs colocalize both in spontaneous and agrin-induced clusters. While MuSK is normally restricted to the motor endplate in adult muscle, denervation results in its extrajunctional expression, although a discernible concentration of MuSK remains localized to the motor endplate even 14 days after denervation. Extrajunctional MuSK is first apparent 3 days after denervation and is sharply reduced upon reinnervation. Muscle paralysis also markedly alters the expression of MuSK in adult muscle and results in increased expression of MuSK as well as increased transcription of MuSK mRNA by extrasynaptic myonuclei. Together, these findings demonstrate that MuSK expression is highly regulated by innervation, muscle activity, and agrin, while the distribution of MuSK is precisely coordinated with that of the AChR.

Regression of polyneural innervation in the human psoas muscle.

During the early stages of mammalian ontogeny muscle fibres are innervated by more than one axon. This polyneural innervation is replaced by mononeural innervation in the course of development. The regression of polyneural innervation in the psoas muscle in the human is the topic of the present study. Innervation patterns were studied in fetuses from 15 1/2 weeks of post menstrual age (PMA) and in babies until 80 weeks PMA (40 weeks after term age) and compared to data from two adults. Motor endplates were stained by a combined acetylcholinesterase stain. Innervation patterns and motor endplate morphology were studied and the sizes of endplates were measured. As a main result of our study polyneural innervation of the psoas muscle remains at a level of about 2 endings per endplate (range 1-5 terminals) until 18-25 weeks PMA and decreases thereafter. From 52 weeks PMA (12 weeks post term) onwards, muscle fibres are predominantly mononeurally innervated. During development the morphology of the terminal patterns of the nerve endings becomes more complex and the size of endplates increases, implying that the adult pattern of muscle innervation is reached at the age at which a major functional transformation in the neurobehavioural repertoire occurs (i.e. the end of the second and the beginning of the third month.

Developmental regulation of membrane traffic organization during synaptogenesis in mouse diaphragm muscle.

In innervated adult skeletal muscles, the Golgi apparatus (GA) displays a set of remarkable features in comparison with embryonic myotubes. We have previously shown by immunocytochemical techniques, that in adult innervated fibers, the GA is no longer associated with all the nuclei, but appears to be concentrated mostly in the subneural domain under the nerve endings in chick (Jasmin, B. J., J. Cartaud, M. Bornens, and J.-P. Changeux. 1989. Proc. Natl. Acad. Sci. USA. 86:7218-7222) and rat (Jasmin, B. J., C. Antony, J.-P. Changeux, and J. Cartaud. 1995. Eur. J. Neurosci. 7:470-479). In addition to such compartmentalization, biochemical modifications take place that suggest a functional specialization of the subsynaptic GA. Here, we focused on the developmental regulation of the membrane traffic organization during the early steps of synaptogenesis in mouse diaphragm muscle. We investigated by immunofluorescence microscopy on cryosections, the distribution of selected subcompartments of the exocytic pathway, and also of a representative endocytic subcompartment with respect to the junctional or extrajunctional domains of developing myofibers. We show that throughout development the RER, the intermediate compartment, and the prelysosomal compartment (mannose 6-phosphate receptor-rich compartment) are homogeneously distributed along the fibers, irrespective of the subneural or extrajunctional domains. In contrast, at embryonic day E17, thus 2-3 d after the onset of innervation, most GA markers become restricted to the subneural domain. Interestingly, some Golgi markers (e.g., alpha-mannosidase II, TGN 38, present in the embryonic myotubes) are no longer detected in the innervated fiber even in the subsynaptic GA. These data show that in innervated muscle fibers, the distal part of the biosynthetic pathway, i.e., the GA, is remodeled selectively shortly after the onset of innervation. As a consequence, in the innervated fiber, the GA exists both as an evenly distributed organelle with basic functions, and as a highly differentiated subsynaptic organelle ensuring maturation and targeting of synaptic proteins. Finally, in the adult, denervation of a hemidiaphragm causes a burst of reexpression of all Golgi markers in extrasynaptic domains of the fibers, hence showing that the particular organization of the secretory pathway is placed under nerve control.

Compartmentalized transcription of acetylcholine receptor genes during motor endplate epigenesis.

In the adult motor endplate the acetylcholine receptor protein (AChR) is strictly localized under the motor nerve ending, whereas in the noninnervated myotube it is distributed all over the surface of the cell. The genesis of this anisotropic distribution involves a differential regulation of AChR gene transcription. In situ hybridization with AChR subunit probes discloses high levels of unspliced and mature mRNA all over differentiating myotubes. After the entry of the exploratory motor axons, the mRNA clusters located outside the endplate decrease in number and become restricted to the subneural "fundamental" nuclei. Denervation causes a reappearance of unspliced and mature mRNA in extrajunctional areas. A compartmentalized expression of AChR genes take place during endplate formation. Chronic paralysis of the embryo interferes with the disappearance of extrajunctional AChR that, thus, represents an electrical activity-dependent repression of AChR genes. The entry of Ca2+ ions through the sarcolemmal membrane during electrical activity and the activation of protein kinase C plausibly contribute to this membrane-to-gene regulation. The maintenance and late increase in AChR number at the endplate requires the intervention of an anterograde signal or signals, of neural origin. Several factors have been suggested to play a role in this process, such as an acetylcholine receptor-inducing activity (ARIA), ascorbic acid, or calcitonin gene-related peptide (CGRP), a peptide known to coexist with acetylcholine in spinal cord motoneurons. In cultured chick muscle cells, CGRP increases the concentration of surface AChR and alpha-subunit unspliced and mature mRNA and stimulates membrane-bound adenylate cyclase, suggesting that distinct second messengers are involved in the regulation of AChR biosynthesis by electrical activity and by CGRP. The data are interpreted in terms of a model in which it is assumed that (i) in the adult muscle fiber, different stages of gene expression occur in the nuclei in subneural and extrajunctional areas, and (ii) different second messengers elicited by neural factors or electrical activity regulate the state of transcription of these nuclei via trans-acting allosteric proteins binding to cis-acting DNA regulatory elements. The upstream flanking regions of several of the AChR subunit genes reveal ubiquitous DNA elements such as TATA and CAAT boxes, Sp1 binding sites and SV40 core enhancer sites, and muscle-specific MyoD (CANNTG) elements. The contribution of some of these elements to the differential regulation of the multiple AChR subunits is discussed.

Progressive restriction of synaptic vesicle protein to the nerve terminal during development of the neuromuscular junction.

Antibodies to synaptic vesicle (SV) proteins and to neurofilament (NF) proteins were used to investigate presynaptic differentiation and its relation to the formation of acetylcholine receptor (AChR) clusters at developing mouse neuromuscular junctions. At all times during development, SV proteins and NF proteins were segregated into neighboring, but separate regions of the presynaptic neurite. At embryonic day (ED) 14 SV proteins were present throughout preterminal neurites but at later ages became progressively restricted to the distal parts of the neurites. NF proteins occupied a more proximal region that extended distally during development until NF proteins occupied the entire axon up to the terminal. The restriction of SV proteins exclusively to the terminal did not occur until the second postnatal week. At the time of their first appearance (ED 14), up to 50% of AChR clusters were not associated with neurites; precise colocalization required 12-36 hr to develop. These findings demonstrate a progressive restriction of both pre- and postsynaptic components to the synapse during development.

Localization of nicotinic acetylcholine receptor alpha-subunit transcripts during myogenesis and motor endplate development in the chick.

In 15-d-old chick latissimi dorsi muscles, the nicotinic acetylcholine receptor (AChR) alpha-subunit mRNA is densely accumulated at the level of subsynaptic nuclei of the motor endplate (Fontaine et al., 1988). In this paper, using in situ hybridization with genomic probes, we further show that the expression of the AChR alpha-subunit gene in the embryo, revealed by the accumulation of mature mRNAs, starts in myotomal cells and persists during the first stages of muscle development in a majority of muscle nuclei. Subsequently, the distribution of AChR alpha-subunit mRNAs becomes restricted to the newly formed motor endplates as neuromuscular junctions develop. To assess the transcriptional activity of individual nuclei in developing muscles, a strictly intronic fragment of the AChR alpha-subunit gene was used to probe in situ the level of unspliced transcripts. AChR alpha-subunit unspliced transcripts accumulate around a large number of sarcoplasmic nuclei at embryonic day 11, but can no longer be detected at their level after embryonic day 16 in the embryo. A similar decrease in the accumulation of AChR alpha-subunit transcripts is observed between day 4 and day 6 in primary cultures of muscle cells. On the other hand, in vivo denervation and in vitro blocking of muscle electrical activity by the sodium channel blocker tetrodotoxin results in an increase in the labeling of muscle nuclei. Yet, only 6% of the muscle nuclei appear labeled by the strictly intronic probes after denervation. The possible significance of such heterogeneity of muscle nuclei during motor endplate formation in AChR gene expression is discussed.

Dynamics of soleplate formation.

Immunohistochemical techniques with anti-desmin, anti-acetylcholine receptor and anti-fibronectin antisera and autohistoradiography were used to determine the dynamics of neuromuscular synaptogenesis. Fast twitching muscles were taken from chick embryos at 5 to 14 days of incubation. "Primitive eminences" at terminal arborizations of motor neurons were composed of Karnowsky positive, anti-desmin and anti-acetylcholine receptor positive cells which contained sites bound to alpha-bungarotoxin. These cells, characterized as myoblasts, fused with the myotubes during formation of neuromuscular junctions in the sites of contact with terminal arborizations of motor neurons. Their nuclei and cytoplasmic organelles become the nuclei and organelles in the soleplate.

Early development of two types of nicotinic acetylcholine receptors.

Functional changes of acetylcholine receptor (AChR) channels in embryonic Xenopus myotomal muscle cells were examined during their development in culture. Single-channel currents evoked by 50 or 500 nM ACh were measured using the patch-clamp technique. In Xenopus myocytes the first emergence of AChRs takes place at about stage 20 (Nieuwkoop and Faber). Myotomes were dissociated at very early stages and plated in culture. Single-channel currents through AChRs were recorded at times ranging from a few hours (stage 21) to several days (stage 47) after the first emergence of AChRs. Two classes of AChR channel were recorded: One class had a low conductance with a long burst duration (low-conductance channel), and the other had a high conductance with a short burst duration (high-conductance channel). Both of these classes were active from the earliest time recorded (stages 21-24). One effect of development was a shift in the relative activity of the low- and high-conductance channels. Initially (stages 21-24), the low conductance channels predominated, accounting for over 95% of the observed events. After 3 d in culture, however, high- and low-conductance events occurred with roughly equal frequency. The other effect of development was a 4-fold decrease in the mean burst length of the low-conductance channel. The decrease in burst length took place rapidly, with about 60% of the change occurring within 24 hr in culture. The burst length of the high-conductance channel remained virtually constant during development, as did the unitary conductance of both channels and the voltage dependence of their mean burst lengths. The developmental change in the proportion of low- and high-conductance channels is likely due to the increased insertion of new high-conductance channels. However, the molecular mechanism of the shortening of burst length of the low-conductance channel is unknown.

Immunological evidence for a change in subunits of the acetylcholine receptor in developing and denervated rat muscle.

We used specific antibodies to gamma, delta, and epsilon subunits to characterize acetylcholine receptor (AChR) in extracts and at endplates of developing, adult, and denervated rat muscle. The AChRs in normal adult muscle were immunoprecipitated by anti-epsilon and anti-delta, but not by anti-gamma antibodies, whereas AChRs in denervated and embryonic muscles were precipitated by anti-gamma and anti-delta, but showed little or no reactivity to anti-epsilon antibodies. In immunofluorescence experiments, AChRs at neonatal endplates bound antibodies to gamma or delta, but not epsilon, subunit, whereas those in adult muscles bound antibodies to epsilon or delta, but not gamma, subunit. AChRs at denervated endplates and at developing endplates between postnatal days 9 and 16 bound all three antibodies. We conclude that the distribution of gamma and epsilon subunits of the AChR parallels the distribution of AChRs with embryonic and adult channel properties, respectively.

Brachial muscles of dystrophic chick embryos atypically sustain interaction with thoracic nerves.

Previous analyses of experimental chick embryos of normal lineage demonstrate the inability of brachial muscles to sustain a successful union with foreign nerves derived from a thoracic neural tube segment transplanted to the brachial region at day 2 in ovo (day 2E). The present experiments were performed to determine if mutant chick embryos afflicted with hereditary muscular dystrophy would respond similarly to this experimental manipulation. Using the same criteria applied to our analysis of experimental normal embryos, our results demonstrated that dystrophic brachial muscles were capable of maintaining a compatible union with foreign thoracic nerves throughout the experimental period analysed. Significant muscle growth occurred, intramuscular nerve branches were maintained, motor endplates formed and wing motility was equivalent to that of unoperated dystrophic embryos. Thus, foreign nerves rejected by normal brachial muscles were accepted by brachial muscles of the mutant dystrophic embryo.

Redistribution of acetylcholine receptors on developing rat myotubes.

The mechanism of formation of acetylcholine receptor (AChR) clusters at developing mammalian endplates was investigated in vitro, using intercostal muscles from embryonic rats. The muscles were explanted in organ culture with the spinal cord attached, as described previously (Ziskind-Conhaim, L., and M. J. Dennis (1981) Dev. Biol. 85: 243-251). AChRs on the myofibers were labeled with [125I]-alpha-bungarotoxin shortly before clusters appeared and subsequently were cultured in unlabeled toxin for 1 day. Autoradiography of the cultured fibers demonstrated the presence of labeled clusters of AChRs indicating that the AChRs in the newly formed clusters arise from AChRs that had previously been uniformly distributed on the muscle surface.